EP0107058A1

EP0107058A1 - Apparatus for monitoring the presence of a person in a bed

Info

Publication number: EP0107058A1
Application number: EP83109524A
Authority: EP
Inventors: Jeff L. Musick; David G. Blaker, Jr.; Robert D. Blaker; Dwight A. Vance
Original assignee: Bed Check Corp
Current assignee: Bed Check Corp
Priority date: 1982-09-30
Filing date: 1983-09-24
Publication date: 1984-05-02
Also published as: AU2124183A; IL69829A; NZ205719A; DE3382141D1; EP0191906A3; GR79658B; ATE29325T1; ATE60455T1; AU562562B2; EP0191906B1; DE3373376D1; IL83381A; NO880702L; JPS59501880A; NO880702D0; EP0191906A2; NO162587C; DK264384D0; NO842056L; EP0107058B1

Abstract

Apparatus for monitoring the presence of a person in a bed comprises a switching device (10) and a monitoring device (110). The switching device (10) comprises a flexible base member (12) having an aperture (22) therethrough, sandwiched between two conductive members (28, 34) and covered with two cover members (36, 40). When a patient lies on the switching device, the base member is deformed allowing the two conductive members to close the circuit. The monitoring device (110) comprises a binary signal generator (112), a time delay (124) which produces a signal when the signal generator has been operated for a predetermined time, a latching device (130), an alarm signal generator (142) and an alarm control device (132) for varying the nature of the alarm signal produced by the generator.

Description

This invention relates to an apparatus for monitoring the presence of a person in a bed. The apparatus is primarily intended for monitoring the presence or absence of a hospital patient from a bed, but may obviously be used for monitoring persons in environments other than hospitals.
A problem continually encountered in hospitals is that of patients leaving their beds when the patients are not in a condition such that they can safely be trusted out of bed. Many instances have been reported of elderly or infirm patients leaving hospital beds and falling, breaking bones or otherwise causing injury to themselves. The patients are sometimes disoriented and confused because of the unfamiliar hospital environment or the effect of drugs used for therapeutic purposes, and such disorientation or confusion can cause the patients to wander, the patients even sometimes leaving the hospital altogether. For these reasons, it is important that hospital staff be apprised if a patient leaves a hospital bed, and several types of prior art monitoring devices for this purpose have previously been developed.
In order for such monitoring equipment to function properly in order to indicate that a patient has left his or her bed, a convenient, reliable switch mechanism must be provided to open and close an electrical circuit. This invention seeks to provide such a switch mechanism.
It has also been found that, when using the prior art monitoring equipment, that the nature or character of the alarm signal to be generated and the delay time between the first indication by the switch mechanism of the patient leaving the bed and the generation of an alarm indicating the absence of the patient from the bed are very important. Accordingly, this invention seeks to provide such a monitoring apparatus in which the nature of the alarm signal can be varied.
Accordingly, in one aspect this invention provides an apparatus (hereinafter referred to as the switching device of the invention) for monitoring the presence of a person in a bed, this apparatus being characterized by a thin base member formed of insulating flexible material and having a pair of surfaces on opposed sides thereof and an aperture passing through the base member and through this pair of surfaces. First and second, thin, electrically conductive members each having dimensions not substantially greater than those of the base member and each having a pair of surfaces on opposed sides thereof are disposed on opposite sides of the base member so that one of the surfaces on the first conductive member is affixed to one of the pair of surfaces on the base member and one of the surfaces on the second conductive member is affixed to the other of the pair of surfaces on the base member. First and second thin, non-conductive cover members are affixed to the surfaces of the first and second conductive members respectively which are not affixed to the base member; the cover members are formed of larger dimensions than the base member and the conductive members so that the peripheral portions of the cover members protrude outwardly beyond the periphery of the conductive members and base member, the peripheral portions of the cover members being sealed to one another. Finally, the switching device of the invention comprises first and second conductors connected between the cover members to the first and second conductive members respectively, these first and second conductors extending through the cover members. The switching device of the invention is arranged so that, when the base member is in its undeformed state, it holds the conductive members spaced apart but that, when the apparatus is subjected to the pressure of a person lying thereon, the base member deforms, thereby allowing the two conducting members to contact one another via the aperture in the base member.
In another aspect, this .invention provides apparatus (hereinafter referred to as the monitoring device of the invention) for monitoring a person in a bed, this apparatus comprising a binary signal generator capable of producing a first signal when the person is in the bed and a second signal when the person is absent from the bed, a time delay for producing a signal after the binary signal generator has generated its second signal for a predetermined time interval, a latching device responsive to the signal from the time delay and an alarm signal generator capable of generating an alarm signal. The monitoring device of the invention is characterized in that it comprises a timer capable of producing signal pulses at predetermined intervals, in that the time delay responds to the signals from both the binary signal generator and the timer and in that it further comprises an alarm control device capable of varying the nature of the alarm signal produced by the alarm signal generator.
The switching device of the invention is intended to be placed in the bed to be monitored underneath the person therein so that while the person is lying in the bed the base member will be deformed, thus allowing the two conductive members to contact one another via the aperture in the base member and thereby establishing electrical contact between the two conductors. (All references herein to "conductive" and "insulating" and words of similar import refer to electrical conduction or insulation.) Thus, while the person is lying down on the bed on the switching device, electrical contact will exist between the two conductors but when the person is out of the bed the switching device will be open. Obviously, it is desirable that the switching device be in the form of a thin mat having a thickness much less than its horizontal dimensions; not only does the provision of this type of switching device increase the comfort of the person being monitored, but provided the mat is appropriately sized and appropriately located in the bed the switching device will be open when the person is off the sensing device even if the person is still sitting on the edge of the bed and it will thus be possible to detect the person leaving the bed before the person wanders from the immediate vicinity thereof.
Desirably, in the switching device of the invention, the base member, the two conductive members and the two cover members are all substantially rectangular, though any or all of these members may have rounded corners if desired. Preferred dimensions for the base member are approximately 1.6mm. thick, 9 to 12.7cm.. wide and 63.5 to 101.6cm. long. The aperture in the base member is desirably generally rectangular, 4.5 to 5.7cm. wide and having a length about 4-5cm. less than the length of the base member. Obviously, it is desirable that the aperture in the base member be centrally positioned. An appropriate insulating flexible material for forming the base member is high-density polyethylene foam.
As already mentioned, in the switching device of the invention, two thin, electrically conductive members are affixed to the opposed surfaces of the base member. These electrically conductive members may have the form of metal foils, metal foils backed with plastic or metalized plastic material (such metalized plastic material may be produced, for example, by applying electroconductive ink to a polyester or other film) and are conveniently secured to the base member by adhesive. Thus, when the base member is in its undeformed state, it supports the conductive members spaced apart from one another by a distance approximately equal to the thickness of the base member. Two conductors are electrically conducted one to each conductive member; conveniently, the two connectors are brought together within a single cable. The cover members, which are conveniently made of plastic serve to cover the conductive members and base member; the sealing of the peripheral portions of the cover members to one another serves to completely seal the apparatus so that the person being monitored is not exposed to electrical shocks from the conductors or the conductive members when the apparatus is placed in the bed.
The switching device of the invention can be placed in any convenient position beneath the person in the bed; thus, for example, the switching device can be placed beneath sheets, bedding or similar covers positioned on top of the mattress, and the switching device need not come into direct contact with the person when the person leaves the bed, the rigidity of the device, and particularly the resilience of the flexible base member, sufficient to cause the conductive members to separate from one another, thereby opening the switching device to indicate the absence of the person from the bed.
In the monitoring device of the invention, although other types of timer may be used, the timer preferably comprises a frequency divider. Such a timer is conveniently of a form which can receive alternating current from the mains or another appropriate source and divide it at an appropriate rate to provide a signal pulse at predetermined intervals, conveniently about one second. These signal pulses from the timer are passed to the time delay, which also receives the signals from the binary signal generator. By monitoring the signals from both the binary signal generator and the timer, the time delay is enabled to produce a signal after the binary signal generator has generated its second signal (indicating the absence of the person from the bed) for a predetermined time period, as measured by the number of signal pulses produced by the timer. The time delay is conveniently in the form of a digital counter and is also desirably provided with a selector switch to enable a number of different periods of delay to be selected. Since movement of the person within the bed or restlessness of the person may cause occasional short-lived second signals from the binary signal generator, it is important to be able to select an appropriate time delay for the monitoring device of the invention so that such movement or restlessness of the person being monitored do not cause spurious alarm signals.
The binary signal generator used in the monitoring device of the invention is preferably a switching device of the invention. In a particular preferred form of switching device for use with the monitoring device of the invention, the electrically conductive members and cover members are combined in the form of first and second sheets of flexible insulating material each having one face covered with a thin layer of flexible, electrically conductive material, the conductive material being in contact with the base member.
The latching device used in the monitoring device of the invention can be a flip-flop (conveniently any one of a number of commercially available forms of this device) and serves to monitor the signal produced by the time delay; when the time delay produces a signal, this signal is supplied to the set terminal of the flip-flop, thereby producing appropriate output voltages at the Q and Q terminals. The outputs from the Q and Q terminals of the flip-flop can then be used by the alarm control device to cause appropriate alarm signals to be generated by the alarm signal generator. The latching action of the flip-flop ensures that once the time delay has produced a signal, the latching device will cause an alarm signal to be generated indefinitely until the latching device is reset. Thus, it is desirable that the monitoring device of the invention include a resetting device for resetting this latching device and this resetting device be capable of automatically resetting the latching device.
The output of the latching device is fed to the alarm control device which is capable of varying the nature of the alarm signal produced by the alarm signal generator. Preferably, the alarm control device selects one of a plurality of possible alarm signals, the possible alarm signal desirably including any one or more of a single voltage pulse of predetermined duration, a steady predetermined voltage, and a series of spaced pulses of predetermined voltage. Such selection of the appropriate form of alarm signal by the alarm signal generator ensures compatibility of the monitoring device of the invention with a variety of nurse call or similar systems. Conveniently, the alarm signal generator comprises a relay which receives a signal from the alarm control device, this relay serving to provide a predetermined voltage on a pair of conductors which extend from the room of the person being monitored to a nursing or similar station so that an audible, visual or other type of alarm can be generated to call the attention of the nurses or other attendants. In many cases, it may be desirable to provide a separate alarm, such as an audible oscillator signal or a lamp on the monitoring device itself so that functioning of the latching device will be immediately apparent to nursing or similar personnel in the room of the person being monitored. As already mentioned, the apparatus very desirably includes a resetting device for resetting the latching device. Such resetting means may comprise a switch on the bed of the person being monitored which can be pressed by an attendant to reset the latching device and/or a reset switch which will reset the latching device after the person being monitored has been put back in bed and the switching device in the bed has again become closed.
Preferred embodiments of the invention will now be described, though by way of illustration only, with reference to the accompanying drawings in which:

Fig. 1 is a top plan view of a preferred switching device of the invention;
Fig. 2 is an enlarged top plan view of part of.the switching device shown in Fig. 1 with various parts broken away to show the internal construction of the switching device;
Fig. 3 is a cross section taken across the width of the device shown in Figs. 1 and 2 (i.e. vertically in Fig. 1); and
Fig. 4 is a circuit diagram of a preferred monitoring device of the invention.

As shown in Figs. 1-3, the preferred switching device of the invention (generally designated 10) comprises a thin base member 12 which is formed of insulating flexible material, conveniently high-density polyethylene foam. The base member 12 is generally rectangular having opposed side edges 14 and 16 and ends 18 and 20. A rectangular aperture 22 is cut centrally through the base member 12, the dimensions of the aperture 22 being approximately 38 to 64mm. smaller in both width and length than those of the base member 12 itself. The base member of the preferred switching device shown in Figs. 1-3 has a length from end 18 to end 20 of approximately 63.5 to 101.6cm., while its width between the side edges 14 and 16 is 9.53 to 12.7cm. The thickness of the base member measured between its surface 24 and its lower surface 30 is approximately 1.6mm. The aperture 22 is conveniently 45 to 57mm. wide and 57.1 to 96.5cm. long, though obviously the dimensions of both the base member and the aperture can be varied quite widely.
As best seen in Figs. 2 and 3, the base member 12 is sandwiched between two thin, electrically conductive members 28 and 34, which are both slightly smaller in both width and length than the base member 12 itself. The lower surface 26 of the conductive member 28 is adhesively affixed to the upper surface 24 of the base member 12, while the upper surface 32 of the conductive member 34 is adhesively affixed to the lower surface 30 of the base member 12. In the preferred switching device shown in Figs. 1-3, the conductive members 28 and 34 are made of thin metal, such as tin foil, aluminum foil or a similar metal surface, but alternatively the conductive members may be made of metal foils bonded to a plastic backing sheet or may be formed of metalized plastic, produced for example by applying electro-' conductive ink to a plastic foil.
The base member 12 and the conductive members 28 and 24 are all sandwiched between two plastic cover members 36 and 40. As shown in Figs. 2 and 3, the upper cover member 36 has its lower surface bonded to the upper surface 38 of the conductive member 28, while the upper surface of the lower cover member 40 is bonded to the lower surface 42 of the conductive member 34. The length and width of the cover members 36 and 40 are both slightly greater than the corresponding dimensions of the base member 12 so that the peripheral portions 44 of the cover members 36 and 40 extend outwardly beyond the periphery of the conductive members 28 and 34 and the base member 12. These peripheral portions 44 of the two cover members are sealed to one another so that no portions of the base member 12 or the conductive members 28 and 34 are exposed.
To provide external connections to the conductive members 28 and 34, a notch 46 is cut in the end 18 of the base member 12 and a cable 48 extends between the peripheral portions 44 of the cover members 36 and 40 into this notch 46. The cable 48 carries a first conductor 50 which is connected, between the cover members 36 and 40, to the conductive member 28, and a second conductor 52 which is similarly connected, between the cover members 36 and 40 to the second conductive member 34.
The preferred switching device of the invention shown in Figs. 1-3 may be easily assembled in the following manner. The base member 12 has the notch 46 cut therein and adhesive is then applied to both the top and bottom surfaces 24 and 30 of the base member. The cable 48 is next inserted into the notch 46 and the conductors 50 and 52 exposed so as to lie adjacent the upper and lower surfaces 24 and 30 respectively of the base member 12. The conductive members 28 and 34 are then positioned on the base member, thereby engaging the connectors 50 and.52 respectively. The cover members 36 and 40 are then placed in the appropriate positions in contact with the conductive members 28 and 34 respectively, adhesive being placed between each cover member and the adjacent surface of the conductive member. The assembled switching device is then pressed together by means of a press or rollers so as to bond the various members together and the peripheral portions 44 of the cover members 36 and 40 are sealed to each other to complete the assembly of the switching device. It will be seen that all the elements used in the switching device of the invention are inexpensive and that the switching device can be expeditiously assembled. Thus, the switching device can be manufactured sufficiently cheaply to be considered a disposable item and its use limited to a single patient, although if desired the device can be sterilized for reuse.
As will be apparent to those skilled in this field, the preferred switching device shown in Figs. 1-3 operates as follows. When the base member is in its undeformed state, as shown in Fig. 3, the flexible base member holds the conductive members 28 and 34 spaced from one another by a distance substantially equal to the thickness of the base member. Thus, in this condition, there is no electrical contact between the conductors 50 and 52. However, when a person lies, sits or otherwise disposes himself upon the switching device, the weight of the person distorts the switching device sufficiently to cause the conductive members 28 and 34 to come into contact with one another via the aperture'22 in the base member 12 at one or more places, thus providing electrical contact between the conductors 50 and 52.
Fig. 4 shows in detail the circuit diagram of a monitoring device (generally designated 110) of the invention, the associated switching device 112_'being shown only schematically. This switching device 112 may be a switching device of the invention as shown in Figs. 1-3 or may be any other appropriate type of binary signal generator capable of producing a first signal when the person is in the bed and a second signal when a person is off the sensing device. Thus, as indicated schematically in Fig. 4, the switching device 112 functions as a biased-open switch, which is closed by a person resting upon the switching device.
One terminal of the switch 116 is grounded, while the other terminal is connected via a line 118 to one input of a time delay 124, which is of the binary counter type. Mains alternating current is supplied via leads 117 to a frequency dividerl20 which effects appropriate frequency division of the alternating input on the leads 117 and produces output pulses at a rate of one per second on a timer output line 122, which is connected to a second input of the time delay 24. The time delay 124 is arranged so that, when the switch 116 is open (thereby indicating that the person is no longer lying on the switching device) the time delay 124 begins to count the number of pulses received from the frequency divider 120.
The time delay 124 is provided with a selector switch (shown schematically as 125) which permits an operator to select a delay period of a predetermined number of seconds (or other interval depending upon the frequency of pulses chosen as the output from the frequency divider 120). The delay selected by the selector switch 125 should be chosen so as to avoid sounding an alarm when the switch 116 is only momentarily open. For example, a restless patient may momentarily lift him or herself up from the bed, thus opening the switch 116 but it is obviously not desirable to sound an alarm for each such momentary opening of the switch 116. Thus, the time delay 124 is used so that an alarm will only be sounded when the switch 116 has been semicon- tinuously for a predetermined period selected by the selector switch 125.
Accordingly, if the switch 116 remains open for longer than the delay period predetermined by the setting of the selector switch 125, the time delay 124 produces an appropriate voltage signal on its output line 126, which extends via an inverter 127 to the S terminal of a flip-flop 130. (The inverter 127 is needed to provide the proper polarity at the S terminal of the flip-flop 130.) The flip-flop 130 serves as a latching device to ensure that, once the time delay 124 has produced an output signal on the line 126, the monitoring device will generate an alarm signal for a sustained period even though the time delay 124 thereafter ceases to produce its output signal.
The R terminal of the flip-flop 130 is connected via a line 131 and a resistor Rl to a terminal designated V, which is connected to a power supply. This power supply (not shown) can be of any conventional type used to supply D.C. voltage for electronic circuits and, as those skilled in the art are well aware, the appropriate voltage will be determined by the particular electronic components used. The line 131 is also connected to ground via a variable capacitor Cl. As explained in more detail below, the line 131 is used to supply a reset signal for resetting the flip-flop 130.
When the flip-flop 130 is energized by receipt of a signal from the time delay 124 on the line 126, appropriate signals are generated at the Q and Q terminals of the flip-flop 130. These signals from the Q and Q terminals are supplied to a group of components, enclosed within the broken boundary 132 in Fig. 4, this group of components comprising an alarm control means. More specifically, the output from the Q terminal of flip-flop 130 is supplied via a line 130A and a variable capacitor C2 to the S terminal of a monostable flip-flop 160'. Between the capacitor C2 and the S terminal of flip-flop 160, the line 130A is connected via a resistor R2 to a terminal V, which is connected to the aforementioned power supply.. The output terminals of monostable flip-flop 160 are bridged by a variable capacity 160C. As indicated by the broken line 160B in Fig. 4, when the monostable flip-flop 160 receives a signal from the flip-flop 130, it generates a signal 160A which comprises a single square voltage pulse of predetermined length, the length of the pulse being determined by the setting of the capacitors 160C. This signal is supplied along a line 156 through a diode 136C to an output line 138.
The output, from the Q terminal of flip-flop 130 is supplied by a line 134 through a diode 136A to the aforementioned output line 138. As shown by the broken lines 158A extending from a line 134B (which also receives the output from the Q terminal of the flip-flop 130), the signal passing through diode 136A is a continuous voltage. The signal from the Q terminal is also supplied from line 134 via lines 134A and 134C to an astable flip-flop 154. This astable flip-flop 154 generates its output signal on a line 155; as indicated by the broken line 154B in Fig. 4, the output signal on line 155 is a series of square voltage pulses of predetermined length, this series of pulses continuing as long as the astable flip-flop 154 receives a signal from the Q terminal of flip-flop 130. The output signal on line 155 is supplied via a diode 136B to the aforementioned output line 138.
Although the output line 138 is shown in Fig. 4 as receiving all three signals passing via the diodes 136A, 136B and 136B, obviously in practice only one output signal is desired on the output line 138 at any time. Selection of the desired one of the three possible signals is effected either by removing two of the diodes 136A, 136B and 136C or, preferably, by selecting the desired signal by means of a selector switch (not shown) which connects the output line 138 to the desired one of the three diodes. It will be apparent that, when the flip-flop 130 is activated by a signal from the time delay 124, if the output line 138 is set to receive the signal via diode 136A, a continuous alarm signal will exist on line 138; if the output line receives the signal via diode 136B, a series of pulses will be passed along the output line 138; and if the output line 138 is connected to the signal passing via diode 136C, a single pulse will be placed on the output line 138.
The signal on the output line 138 passes through an inverter 146. The output from this inverter 146 is supplied to the base of a NPN transistor 140. The emitter of this transistor 140 is grounded, while the collector is connected via the solenoid of a relay 142 and a line 143 to a terminal T connected to the aforementioned power supply. A diode 147 is connected between the base of the transistor 140 and the line 143.
As indicated by the broken line 142A in Fig. 4, the moveable terminal of the relay 142 is designated 142B and is connected between a pair of leads 114 which extend from the monitoring device to a nurses' station or similar location at which personnel are present so that when the relay 142 is energized appropriate signals will be provided at the nurses' station or similar location. Thus, the relay 142 acts as an alarm signal generator, producing alarm signals similar in type to those of the selected input to the line 138.
In order that the monitoring device will provide not only a remote alarm via the lines 114 but also a local alarm which can be seen and heard by personnel in the same room as the person being monitored, the monitoring device is provided with local audible and visual alarms. For this purpose, the Q terminal of flip-flop 130 is connected via lines 134, 134A and 134B to the base of a transistor 148. The emitter of this transistor is grounded, while the collector is connected via a sonic alarm 151 and a visual alarm (shown as a light emitting diode 152), and a resistor R3 arranged in parallel to the sonic alarm 151, to the same terminal V as the coil of the relay 142. It will be apparent that when the flip-flop 130 is energized and a steady signal is present at the Q terminal thereof, transistor 148 will become conducting, thereby sounding the sonic alarm 151 and illuminating the diode 152 to provide local audible and visual alarm signals to personnel in the room of the person being monitored.
As already mentioned, resetting of the monitoring device after an alarm has been sounded is effected at the R terminal of flip-flop 130. For this purpose, this R terminal is connected via lines 131 and 161 and a diode 164A to the Q output of a hold flip-flop 162. The line 131 is also connected via a line 164 and a diode 164B to one terminal of a manually-operable reset switch 168, the other terminal of the switch being grounded. The aforementioned one terminal of the switch 168 is also connected via a line 169 to the R terminal of the flip-flop 162.
The Q terminal of flip-flop 162 is connected via a light emitting diode 162A to a terminal V connected to the aforementioned power supply. The Q terminal of 162 is also connected via a diode 170 to a hold input terminal of the time delay 124. Finally, the S terminal of flip-flop 162 is connected via a resistor R4 to a terminal V connected to the aforementioned power supply, the S terminal also being connected via a normally-open switch 166 and a variable capacitor 167, arranged in parallel, to ground.
The R terminal of flip-flop 162 is provided with a time delay circuit. This time delay circuit comprises an inverter Il, the input terminal of which is connected to line 118. The output from inverter Il is passed through a resistor R5 (this resistor being bridged by a diode 172) to the input of a second inverter 12; the line connecting the resistor R5 and the diode 172 to the input of inverter I2 is grounded via a variable capacitor C3. The output from inverter I2 passes via a capacitor C4 and a line 174 to the aforementioned line 169 connected to the R terminal of flip-flop 162; the line 174 is connected via a resistor R6 to a terminal V connected to the aforementioned power supply.
When placing a patient in the bed equipped with the switching device 112, the switch 166 is closed manually, thus grounding the S terminal of flip-flop 162, causing the Q terminal thereof to go low and turning on the light emitting diode 162A, thereby confirming the status of the flip-flop 162 and showing that the apparatus is ready for operation. After the person has been placed in the bed to be monitored, the reset switch 168 is closed momentarily by hand, thus resetting the flip-flop 162, turning off all the alarms and putting the monitoring device into operation to monitor the patient in the bed. If switch 168 is not reset manually, the circuit provides for automatic resetting of the flip-flop 162 after a time delay of approximately ten seconds provided by the time delay circuit, in order to reduce the possibility of false triggering because the switch 116 may open and close as the person is placed in the bed. Closing the switch 116 causes the output of inverter Il to go positive, thus charging capacitor C3 via resistor R5. When the voltage on C3 reaches an appropriate value, the output of inverter I2 goes to ground, thereby momentarily grounding capacitor C4 and placing a momentary grounding pulse on line 174. This momentary grounding pulse conveyed to the R terminal of flip-flop 162 via line 169 resets flip-flop 162, thereby removing the whole signal previously passed through diode 170 to the hold input of time delay 124. If switch 16 is opened before the appropriate time delay has elapsed i.e. before the voltage on C3 has risen to a value sufficient to cause a grounding pulse to be applied to the R terminal of flip-flop 162, diode 172 will quickly discharge C3 so that when switch 116 closes C3 always starts charging from zero voltage and thus the reset pulse will only be applied after switch 116 has been closed for the time delay period. Obviously, switch 168 may be closed manually at any time to reset any alarm that has sounded.

Claims

1. Apparatus (10) for monitoring the presence of a person in a bed, the apparatus-being characterized by:

a thin base member (12) formed of insulating flexible material and having a pair of surfaces (24,30) on opposed sides thereof and an aperture (22) passing through the base member and through the pair of surfaces (24,30);

first and second thin, electrically conductive members (28,34) each having dimensions not substantially greater than those of the base member and each having a pair of surfaces (26,32,38,42) on opposed sides thereof, one of the surfaces (26) on the first conductive member (28) being affixed to one of the pair of surfaces (24) on the base member (12) and one of the surfaces (32) on the second conductive member (34) being affixed to the other of the pair of surfaces (30) on the base member (12);

first and second thin, non-conductive cover members (36,40) affixed to the surfaces (38,42) on the first and second conductive members (28,34) respectively which are not affixed to the base member (12), the cover members being of larger dimensions than the base member and the conductive members so that the peripheral portions (44) of the cover members (36,40) protrude outwardly beyond the peripheries of the conductive members (28,34) and base member (12), the peripheral portions (44) of the cover members being sealed to one another; and

first and second conductors (50,52) connected between the cover members (36,40) to the first and second conductive members (28,34) respectively, the first and second conductors (50,52) extending through the cover members (36,40),

such that, when the base member (12) is in its undeformed state, it holds the conductive members (28,34) spaced apart but that, when the apparatus is subjected to the pressure of a person lying thereon, the base member (12) deforms, thereby allowing the two conductive members (28,34) to contact one another via the aperture (22) in the base member (12).

2. Apparatus as claimed in claim 1 characterized in that the base member (12), the two conductive members (28,34) and the two cover members (36,40) are all substantially rectangular.

3. Apparatus as claimed in claim 1 or 2 characterized in that the base member (12) is formed of high-density polyethylene foam.

4. Apparatus as claimed in claim 1 or 2 characterized in that the base member (12) is substantially 1.6mm. thick.

5. Apparatus (110) for monitoring a person in a bed, the apparatus comprising:

a binary signal generator (112) capable of producing a first signal when the person is in the bed and a second signal when the person is absent from the bed;

a time delay (124) for producing a signal after the binary signal generator has generated its second signal for a predetermined time period;

a latching device (130) responsive to the signal from the time delay; and

an alarm signal generator (142) capable of generating an alarm signal,

the apparatus being characterized in that it further comprises a timer (120) capable of producing signal pulses at predetermined intervals, in that the time delay (124) responds to the signals from both the binary signal generator (112) and the timer (120), and in that the apparatus further comprises an alarm control device (132) capable of varying the nature of the alarm signal produced by the alarm signal generator (142).

6. Apparatus as claimed in claim 5 characterized in that the timer (120) comprises a frequency divider.

7. Apparatus as claimed in claim 5 or 6 characterized in that the binary signal generator (112) is an apparatus as defined in any one of claims 1 to 4.

8. Apparatus as claimed in claim 5 or 6 characterized in that the binary signal generator (112) is a mat (10) comprising:

a thin base member (12) formed of a compressible insulating material and having a pair of surfaces (24,30) on opposed sides thereof and an aperture (22) pasing through the base member (12) and through the pair of surfaces (24,30);

first and second sheets (38,42) of flexible insulating material each having one face (38,42) covered with a thin layer (28,34) of flexible, electrically conductive material, the first sheet (36) having its conductive material layer (28) in contact with one of the pair of surfaces (24) on the base member (12) and the second sheet (40) having its conductive material layer (34) in contact with the other of the pair of surfaces (30) on the bse member (12); and

first and second electrical conductors (50,52) attached to the conductive material layers (28,34) on the first and second sheets (36,40) respectively,

such that, when the base member (12) is in its undeformed state, it holds the conductive material layers (28,34) on the first and second sheets (36,40) spaced apart from one another but that when the mat (112) is subjected to the pressure of a person disposed thereon, the base member (12) deforms, thereby allowing the two conductive material layers (28,34) to contact one another via the aperture (22) in the base member (12), and thus establishing a connection between the two electrical conductors (50,52).

9. Apparatus as claimed in claim 5,6 or 8, characterized in that the alarm control device (132) varies the nature of the alarm signal produced by the alarm signal generator (142) by selecting one of a plurality of possible alarm signals.

10. Apparatus as claimed in claim 9 characterized in that the possible alarm signals include any one or more of a single voltage pulse of predetermined duration, a steady predetermined voltage and a series of spaced pulses of predetermined voltage.

11. Apparatus as claimed in any one of claims 5,6 or 8 characterized by a resetting device (68) for resetting the latching device, the resetting device being capable of automatically resetting the latching device.